Where will species go? Revolutionising projections of species distributions with climate change. Improving our capacity to predict climate change impacts on biodiversity is a National Research Priority and a priority under the National Biodiversity and Climate Change Action Plan (2004-2007). Our research will revolutionise the field of bioclimatic modelling by enabling the probability of losses/gains in species distributions to be calculated. This will enable policy makers to identify vulnerable ....Where will species go? Revolutionising projections of species distributions with climate change. Improving our capacity to predict climate change impacts on biodiversity is a National Research Priority and a priority under the National Biodiversity and Climate Change Action Plan (2004-2007). Our research will revolutionise the field of bioclimatic modelling by enabling the probability of losses/gains in species distributions to be calculated. This will enable policy makers to identify vulnerable species and provides a strong framework for prioritizing areas for research and monitoring. Our research will interface two disciplines, earth and biological sciences, and establish a new international collaboration that will ensure Australia is at the forefront of a rapidly developing research field. Read moreRead less
Stable water isotopic simulation and analysis to improve Earth System models and deliver better predictions of Australian water resource vulnerability. As Australia's challenges in environmental sustainability rival those anywhere on Earth, we must be clever in our diagnosis of susceptibility and insightful in proposed remedies. Climate change and variability have impacts on people and society that must be managed effectively whatever their causes. Of importance to Australia is the availabilit ....Stable water isotopic simulation and analysis to improve Earth System models and deliver better predictions of Australian water resource vulnerability. As Australia's challenges in environmental sustainability rival those anywhere on Earth, we must be clever in our diagnosis of susceptibility and insightful in proposed remedies. Climate change and variability have impacts on people and society that must be managed effectively whatever their causes. Of importance to Australia is the availability of water for drinking and agriculture. The new, interdisciplinary ARC network for Earth System Science provides models for novel and synergistic research such as naturally occurring water isotopes as a tool for improving predictive skill and confidence. We exploit these and leverage international programs to improve regional hydro-climate and water resource understanding in Australia.Read moreRead less
Physical, Chemical and Radiative Characteristics of Australian Continental Aerosols. Australian desert dust, and the biomass burning aerosol particles produced in the top-end burning season, have the potential to impose an environmental burden not only on Australia, but also on the surrounding region. While most of the world's major aerosol types have been well studied in recent years, these two remain largely unknown. There are good reasons to believe that Australian aerosols are different from ....Physical, Chemical and Radiative Characteristics of Australian Continental Aerosols. Australian desert dust, and the biomass burning aerosol particles produced in the top-end burning season, have the potential to impose an environmental burden not only on Australia, but also on the surrounding region. While most of the world's major aerosol types have been well studied in recent years, these two remain largely unknown. There are good reasons to believe that Australian aerosols are different from many others. We therefore intend to fully characterize their relevant properties, so we may monitor them from space, and evaluate their environmental impacts.Read moreRead less
A Dynamical Systems Approach to Mapping Southern Ocean Circulation Pathways. Climate change can be expected to have complex, long-term consequences for Australia's biodiversity, for our agricultural and marine production systems, and for regional communities. The Southern Ocean is a critical driver of global climate, connecting the three major oceanic basins. Using sophisticated mathematics to analyse state-of-the-art global ocean models, this project will create a detailed picture of hitherto i ....A Dynamical Systems Approach to Mapping Southern Ocean Circulation Pathways. Climate change can be expected to have complex, long-term consequences for Australia's biodiversity, for our agricultural and marine production systems, and for regional communities. The Southern Ocean is a critical driver of global climate, connecting the three major oceanic basins. Using sophisticated mathematics to analyse state-of-the-art global ocean models, this project will create a detailed picture of hitherto invisible Southern Ocean circulation 'pathways'. The newly discovered pathways will greatly enhance our understanding of the Southern Ocean circulation, lead to improved coupled climate models, and increase our ability to predict future climate change and threats to marine populations. Read moreRead less
Abrupt Southern Hemisphere Climate Change: The Role Of The Southern Ocean Thermohaline Circulation. Australia's climate is extreme, with harsh droughts, severe bushfire seasons, climate change, soil loss, and salinity all posing potentially enormous socio-economic challenges over the next ten-fifty years. Research into climate change and climate variability is thus highly significant for Australia, and will underpin efforts to protect our biodiversity and ensure the nation's environmental sustai ....Abrupt Southern Hemisphere Climate Change: The Role Of The Southern Ocean Thermohaline Circulation. Australia's climate is extreme, with harsh droughts, severe bushfire seasons, climate change, soil loss, and salinity all posing potentially enormous socio-economic challenges over the next ten-fifty years. Research into climate change and climate variability is thus highly significant for Australia, and will underpin efforts to protect our biodiversity and ensure the nation's environmental sustainability. We propose to launch a major new study of the stability of the Southern Ocean's thermohaline circulation and its role in global climate. This work could have significant long-term benefits for those sectors of society sensitive to shifts in climate; including agriculture, energy, freshwater supply, health, and tourism.Read moreRead less
Dynamic networks in a patchy landscape: will species interactions adjust to increased climatic extremes? This project addresses pressing questions on how increased climatic extremes will affect species diversity in arid Australia, building on the longest ecological dataset available for the continent's vast but fragile inland landscapes. Our tests of key ideas about strong interactions among species, their role in building resilient communities and conserving biodiversity, will generate consider ....Dynamic networks in a patchy landscape: will species interactions adjust to increased climatic extremes? This project addresses pressing questions on how increased climatic extremes will affect species diversity in arid Australia, building on the longest ecological dataset available for the continent's vast but fragile inland landscapes. Our tests of key ideas about strong interactions among species, their role in building resilient communities and conserving biodiversity, will generate considerable international interest, while our focus on interactions of species at water sources will address knowledge gaps to inform best practice in managing converted pastoral lands. The results will contribute to retaining healthy functioning ecosystems, and the vital production systems they support, as the global climate changes.Read moreRead less
Modelling long-term hydrological persistence using hidden state Markov models. Long-term climatic persistence has a pronounced effect on engineering risk assessment of drought and flood severity. Accurate risk assessment is essential for economic design of water resource and flood defence infrastructure. A new, physically realistic, framework for stochastic modelling of persistence is developed, in which the probability distributions of hydrological variables depend on underlying climatic states ....Modelling long-term hydrological persistence using hidden state Markov models. Long-term climatic persistence has a pronounced effect on engineering risk assessment of drought and flood severity. Accurate risk assessment is essential for economic design of water resource and flood defence infrastructure. A new, physically realistic, framework for stochastic modelling of persistence is developed, in which the probability distributions of hydrological variables depend on underlying climatic states. These states are not directly observable, and occasionally change in a random manner. The research program, involving three PhD projects, will develop: estimation techniques and software using climate indices and multi-site data; a new approach to flood risk regionalisation; and seasonal rainfall forecasting methods.Read moreRead less
Do terrestrial processes intensify Australian droughts ? Australia's agricultural productivity is strongly affected by climate, climate variability and climate change. Recent climate changes in Western Australia forced adaptation strategies costing $500 million while the anomalously intense 2002 Murray-Darling Basin drought significantly affected agriculture. Any further intensification of droughts would affect Australia's rural economy. This proposal will assess the role of terrestrial processe ....Do terrestrial processes intensify Australian droughts ? Australia's agricultural productivity is strongly affected by climate, climate variability and climate change. Recent climate changes in Western Australia forced adaptation strategies costing $500 million while the anomalously intense 2002 Murray-Darling Basin drought significantly affected agriculture. Any further intensification of droughts would affect Australia's rural economy. This proposal will assess the role of terrestrial processes, linked to increasing CO2, in causing the drought intensification and declines in rainfall. This will provide knowledge that will guide the development of future environmental management strategies.Read moreRead less
The historical environment of Angkor: an investigation of synergy between people and landscape. Understanding the complex inter-relationship between humans and the natural environment is of critical importance. The use of geo-scientific techniques to interpret historical environmental records provides a useful tool for obtaining this knowledge. Using the medieval city of Angkor, Cambodia, as a case study, the proposed research will employ well-established analytical techniques in a new and innov ....The historical environment of Angkor: an investigation of synergy between people and landscape. Understanding the complex inter-relationship between humans and the natural environment is of critical importance. The use of geo-scientific techniques to interpret historical environmental records provides a useful tool for obtaining this knowledge. Using the medieval city of Angkor, Cambodia, as a case study, the proposed research will employ well-established analytical techniques in a new and innovative manner to reconstruct environmental change and cultural adaptation. This research, the first of its kind undertaken at Angkor, will revolutionise our understanding of this World Heritage site, and contribute to a better understanding of the synergy between human culture and its environmental context.Read moreRead less
Characterizing the hydrological cycle using water isotopes, land-surface models and satellite observations. Water is our most precious natural resource. In Australia, it is also our most precarious. The hydrological cycle describes the movement of water between the ocean, atmosphere and land. Understanding the effect and impact that a changing climate might have on the hydrological cycle is critical to securing Australia's water resources. To address these challenges, we must improve our basic u ....Characterizing the hydrological cycle using water isotopes, land-surface models and satellite observations. Water is our most precious natural resource. In Australia, it is also our most precarious. The hydrological cycle describes the movement of water between the ocean, atmosphere and land. Understanding the effect and impact that a changing climate might have on the hydrological cycle is critical to securing Australia's water resources. To address these challenges, we must improve our basic understanding of the water exchange processes within the Earth system. Our project will exploit new technology in ground and space based observation, combined with advanced modeling and measurement capabilities, to develop an improved understanding and characterization of Australian hydrological cycles and aid in assessing climate change related impacts. Read moreRead less